System and method for detecting movement of a mobile asset and controlling operations of the asset based on its movement

ABSTRACT

A system and method detect direction of movement. The system includes at least two radio frequency identification (RFID) readers arranged in different locations. The RFID readers transmit respective location signals from their locations and receive corresponding response signals from a portable electronic device (PED) when the PED is within range to receive the corresponding location signals, respectively. The system includes a controller configured to determine whether the individual response signals received by the RFID readers respectively satisfy a predetermined condition at a first time and a second time after the first time. The controller is configured to determine a direction of movement of the PED relative to the locations of the RFID readers during the first and second times based on whether the response signals respectively satisfy the predetermined condition at the first and second times, and control operations of the PED based on the determined movement of the PED.

RELATED APPLICATION

The present application is a continuation of U.S. patent applicationSer. No. 15/408,055, filed on Jan. 17, 2017. The entire contents of theearlier application are hereby incorporated by reference in theirentirety.

FIELD

The present disclosure relates to a system and method for detecting themovement of a mobile asset based on the use of radio frequencyidentification (RFID). For example, the system and method can beemployed in a building in which various security protocols areimplemented in different areas of the building. The mobile asset may be,for example, a portable electronic device such as a laptop computer, atablet computer, or a smartphone. The system and method of the presentdisclosure continuously validate whether the mobile asset enters, leavesor remains in a particular area over a period of time, and authorize themobile asset to perform certain operations based on the travel orcurrent location of the asset. For example, the system and method canenable and control the operation and/or execution of certain hardwareand software components of the mobile asset based on the detectedmovement and location of the mobile asset.

BACKGROUND INFORMATION

Known RFID implementations are built around the concept of tracking thephysical location of an asset (e.g., a product such as a mobilecomputing device) having an RFID tag affixed thereto. A radio frequency(RF) reader reads the RFID tag. In this scenario, the asset is notself-aware of its RFID-based location as all location information isexchanged between the RFID tag and the RFID reader(s).

US 2016/0088432 discloses a system and method for location-basedsecurity, in which a portable electronic device (e.g., a laptop, tabletcomputer, smartphone, etc.) having an RFID tag receives a proximitysignal from an RFID reader when the portable electronic device is withina predetermined range of the RFID reader. The processor of the portableelectronic device is then configured to control at least one operationof the portable electronic device in accordance with the proximitysignal. For example, the processor of the portable electronic device maybe configured to enable or disable access to executable applications orfiles stored in the portable electronic device. The processor of theportable electronic device may also enable or disable access to at leastone operating system of the portable electronic device, and/or enable ordisable access to at least one hardware component (e.g., a camera) ofthe portable electronic device.

SUMMARY

An exemplary embodiment of the present disclosure provides a system fordetecting direction of movement. The exemplary system includes a firstradio frequency identification (RFID) reader arranged in a firstlocation. The first RFID reader is configured to transmit a firstlocation signal from the first location, and to receive a first responsesignal from a portable electronic device when the portable electronicdevice is within range of the first location to receive the firstlocation signal. The exemplary system also includes a second RFID readerarranged in a second location distinct from the first location. Thesecond RFID reader is configured to transmit a second location signalfrom the second location, and to receive a second response signal fromthe portable electronic device when the portable electronic device iswithin range of the second location to receive the second locationsignal. In addition, the exemplary system includes a controllerconfigured to determine whether the first and second response signalsreceived by the first and second RFID readers respectively satisfy apredetermined condition at a first time and a second time subsequent tothe first time. The controller is also configured to determine adirection of movement of the portable electronic device relative to thefirst and second locations during the first and second times based onwhether the first and second response signals respectively satisfy thepredetermined condition at the first and second times.

An exemplary embodiment of the present disclosure provides a method ofdetecting direction of movement. The exemplary method includestransmitting, from a first radio frequency identification (RFID) readerarranged in a first location, a first location signal from the firstlocation, and transmitting, from a second RFID reader arranged in asecond location distinct from the first location, a second locationsignal from the second location. The exemplary method also includesreceiving, at the first RFID reader, a first response signal from aportable electronic device (PED) when the portable electronic device iswithin range of the first location to receive the first location signaltransmitted by the first RFID reader. In addition, the exemplary methodincludes receiving, at the second RFID reader, a second response signalfrom the portable electronic device when the portable electronic deviceis within range of the second location to receive the second locationsignal transmitted by the second RFID reader. The exemplary method alsoincludes determining, by a hardware processor of a controller, whetherthe first and second response signals received by the first and secondRFID readers respectively satisfy a predetermined condition at a firsttime and a second time subsequent to the first time. In addition, theexemplary method includes determining, by the processor of thecontroller, a direction of movement of the portable electronic devicerelative to the first and second locations during the first and secondtimes based on the determination of whether the first and secondresponse signals respectively satisfy the predetermined condition at thefirst and second times.

BRIEF DESCRIPTION OF THE DRAWINGS

Additional refinements, advantages and features of the presentdisclosure are described in more detail below with reference toexemplary embodiments illustrated in the drawings.

FIGS. 1A-1E are diagrams of an exemplary system of the presentdisclosure at different times to illustrate the detection of motion of aportable electronic device (PED) at the different times.

FIG. 2 is a block diagram illustrating the hardware architecture of aportable electronic device in accordance with an exemplary embodiment.

FIG. 3 is a block diagram illustrating the hardware architectures ofRFID readers in a district of the system of FIGS. 1A-1E, in accordancewith an exemplary embodiment.

FIG. 4 is a block diagram illustrating the hardware architecture of thecontroller of the system of FIGS. 1A-1E, in accordance with an exemplaryembodiment.

FIG. 5 is a chart showing the respective powers of response signalstransmitted by the portable electronic device to RFID readers in theexemplary system during times 1-5 illustrated in FIGS. 1A-1E,respectively.

FIG. 6 is a diagram of an exemplary system for illustrating thedetection of movement of a portable electronic device between two RFIDreaders in different coverage areas.

FIG. 7A is a graph illustrating the measured power of a response signalreceived by RFID reader 1 in FIG. 6 as a portable electronic devicemoves relative to the location of RFID reader 1 in FIG. 6.

FIG. 7B is a graph illustrating the measured power of a response signalreceived by RFID reader 2 in FIG. 7 as the portable electronic devicemoves relative to the location of RFID reader 2 in FIG. 7.

FIG. 8A is a graph illustrating the derivative of power of the responsesignal illustrated in FIG. 7A relative to the distance from RFID reader1 in FIG. 6.

FIG. 8B is a graph illustrating the derivative of power of the responsesignal illustrated in FIG. 7B relative to the distance from RFID reader2 in FIG. 6.

FIG. 9 is a graph comparing the powers of the response signalsillustrated in FIGS. 6A and 6B with their derivatives as illustrated inFIGS. 7A and 7B over time as the portable electronic device movesbetween the RFID readers.

FIG. 10 is a flowchart illustrating a method of detecting direction ofmovement of a portable electronic device using RFID readers, accordingto an exemplary embodiment.

Further areas of applicability of the present disclosure will becomeapparent from the detailed description provided hereinafter. It shouldbe understood that the detailed description of exemplary embodiments isintended for illustration purposes only and is, therefore, not intendedto necessarily limit the scope of the disclosure.

DETAILED DESCRIPTION

This description provides exemplary embodiments only, and is notintended to limit the scope, applicability or configuration of thesystem and method of the present disclosure, or the constituentcomponents of the system of the present disclosure, such as the RFIDreaders, the controller(s) and the portable electronic devices describedherein. Rather, the ensuing description of exemplary embodiments willprovide those skilled in the art with an enabling description forimplementing embodiments of the system and method of the presentdisclosure. Various changes may be made in the function and arrangementof the constituent components of the system and method without departingfrom the spirit and scope of the disclosure as set forth in the appendedclaims. Thus, various embodiments may omit, substitute, or add variousfeatures, procedures or components as appropriate. For instance, itshould be appreciated that in alternative embodiments, the methods maybe performed in an order different than that described, and that varioussteps may be added, omitted or combined. Different aspects and elementsof the embodiments may be combined in a similar manner.

FIGS. 1A-1E illustrate an exemplary system 100 in which the embodimentsof the present disclosure can be implemented. FIGS. 1A-1E illustrate theexemplary system 100 at different times to illustrate the detection ofmotion of a portable electronic device (PED) at the different times.FIGS. 1A-1E illustrate the exemplary system 100 at times 1-5,respectively.

The exemplary system 100 is illustrated in FIGS. 1A-1E as beingimplemented in a building having a plurality of distinct districts and acontroller 130 for those districts. The system of the present disclosureincludes a plurality of RFID readers and the controller 130. In theexample of FIGS. 1A-1E, there are four districts 1-4 illustrated asrooms of the building, and another district H that is a hallway betweenthe rooms. In the illustrated example, there is at least one RFID readerin each district, and each RFID is arranged in a different locationrelative to the other RFID readers in the exemplary system 100. Forinstance, RFID readers 110 and 120 are located in District 1, RFIDreaders 142, 144, 146 and 148 are located in District 2, RFID readers152, 154 and 156 are located in District 3, RFID readers 162 and 164 arelocated in District 4, and RFID readers 172, 172, 176, 178 and 180 arelocated in District H. It is to be understood that the system 100illustrated in FIGS. 1A-1E is an example of the arrangement of a numberof RFID readers in a building, and the present disclosure is not limitedto the illustrated example. The RFID readers may be arranged indifferent locations in the various districts of a building such that thedirectionality and signal power of the RFID readers provide the desiredarea of coverage in the particular districts. For example, the RFIDreaders may be individually arranged on a wall or ceiling of a district,or near the doorway of a district, such as above the doorframe or on thefront or back of a door, depending on the desired area of coverage for aparticular RFID reader.

In the example of FIGS. 1A-1E, a single controller 130 is provided fordistricts 1-4 and H, which are located on a floor of a building, asdescribed above. The present disclosure is not limited to this example.One or more districts can be located on one floor of a building, whileother districts can be located on different floors of the building. Asingle controller 130 can be provided for all the districts on multiplefloors of a building. Alternatively, multiple controllers 130 can beprovided for individual groups or subsets of districts, such as anindividual controller 130 for each individual floor of a building,and/or an individual controller 130 for a selected number of districts(e.g., one controller 130 for ten districts). The number of districtsand controller(s) is customizable based on the building or area to bemonitored. In the case of multiple controllers, one of the controllerscan be designated as the supervisory controller while the othercontrollers are subordinate controllers that provide information on thereadings of the RFID readers to the supervisory controller, which inturn carries out the operative functions of determining a direction ofmovement of a portable electronic device, as described herein. Exemplaryembodiments of the present disclosure are described below using theexample of FIGS. 1A-1E in which there is a single controller 130 forcontrolling the multiple districts 1-4 and H. The controller(s) 130 ofthe system can be communicatively connected to the RFID readers throughwired mediums such as Ethernet wiring and/or through wireless mediumssuch as Wi-Fi, for example.

In the exemplary system 100 illustrated in FIGS. 1A-1E, each of the RFIDreaders respectively has a coverage area dependent on the individualreader's antenna design. As used herein, the term “coverage area” meansan area that an RFID reader illuminates with RF radiation sufficient tofacilitate RFID operation and communications in that area. In RFengineering, the “coverage area” or “coverage pattern” may be describedby parameters for any one or more of (i) the propagation direction, (ii)illumination beam width, (iii) beam range, and (iv) frequency oftransmission (i.e., the frequency at which the RFID transmits RFIDsignals). The coverage area of each RFID reader can be individuallyconfigured. For instance, in the exemplary system 100 illustrated inFIGS. 1A-1E, the various RFID readers can be configured to havedifferent types of coverage areas with respect to the directionality,propagation direction, beam width and/or orientation (i.e.,polarization) of their respective coverage areas. For example, RFIDreaders 110 and 120 in District 1, and RFID reader 164 in District 4each produce coverage beams with propagation directions that are 90°from one another. As used herein, the term “propagation direction” meansthe angle of illumination of the antenna (e.g., transceivers 319, 329 inFIG. 3) of an RFID reader. In the exemplary system 100 of FIGS. 1A-1E,RFID readers 142, 144, 146 and 148 in District 2, RFID readers 152, 154and 156 in District 3, RFID reader 162 in District 3, and RFID readers172, 172, 176, 178 and 180 in District H each have a beam width that isless than 180°. For example, RFID reader 146 in District 2 has a beamwidth of approximately 25°, whereas RFID reader 148 in District 2 has abeam width of approximately 60°. The coverage areas illustrated in theexemplary system 100 of FIGS. 1A-1E are intended to be illustrativeexamples, and the present disclosure is not limited thereto. Accordingto an exemplary embodiment, the coverage area beam width of each RFIDreader can be individually configured from approximately 10°-360°depending on the desired coverage area for a particular location. Oneskilled in the art of antenna design will appreciate how the coveragepattern propagation direction, propagation range, polarization, and beamwidth can be configured in either the elevation or azimuthal directions.While it is possible to configure an RFID reader to have a coverage areabeam width less than 10°, such a narrow coverage area beam width mayresult in a coverage area that may be too narrow to be useful indetecting the movement of a portable electronic device into thatcoverage area. Nevertheless, it should be understood that an RFID readercan be configured to have a narrow coverage pattern, for example, lessthan 10°.

As is known in the art, RFID readers regularly transmit interrogationsignals in their respective coverage areas. The interrogation signalsare radio signals and may be encoded. The frequency of transmission ofthe interrogation signals can be set as desired. In the exemplaryembodiments described below, the interrogation signals are described as“location signals” since the respective interrogation signalstransmitted by each RFID reader are associated with the location of thecorresponding RFID readers. For clarity of illustration, the locationsignals (i.e., interrogation signals) are illustrated for RFID readers142, 144, 146, 152, 154, 156, 162, 172, 176, 178 and 180 as thecorresponding coverage areas of these RFID readers in FIGS. 1A-1E,respectively. In the exemplary system 100 of FIGS. 1A-1E, RFID reader110 transmits location signal 112, RFID reader 120 transmits locationsignal 122, and RFID reader 164 transmits location signal 165. As usedherein, the power of a signal is relative to the amplitude of thesignal, i.e. the amplitude of the electromagnetic wave. According to anexemplary embodiment, the respective power and frequency of the locationsignals transmitted by each RFID reader can be individually customizedto service a particular coverage area. For example, as illustrated inthe exemplary system 100 of FIGS. 1A-1E, the power of the interrogationsignal of RFID reader 152 in District 3 is less than the respectivepowers of the interrogation signals of the RFID readers 154 and 156 inDistrict 3. As such, in the exemplary system 100 of FIGS. 1A-1E, thecoverage area 153 of RFID reader 152 does not extend as far in thedirection of the apex of the coverage area 153 as the correspondingcoverage areas 155 and 157 of RFID readers 154 and 156, respectively. Inaddition, the coverage pattern of RFID reader 152 is smaller than therespective coverage patterns of RFID readers 154 and 156. In theexemplary system 100 of FIGS. 1A-1E, the power of the interrogationsignal transmitted by RFID reader 152 and the propagation pattern ofRFID reader 152 were selected to cover a smaller coverage area 153 thanthe respective coverage areas 155 and 157 of RFID readers 154 and 156,i.e., near the doorway of District 3.

In the exemplary system 100 of FIGS. 1A-1E, RFID reader 172 isillustrated as having two different coverage areas with differentpropagation patterns. An RFID reader according to the present disclosurecan have different coverage areas with different propagation directionsby having multiple antennae each being configured to service aparticular coverage area with a particular propagation direction. In theexemplary system 100 of FIGS. 1A-1E, the coverage areas, propagationdirections, frequency of transmission of the location signals, and powerat which the location signals are transmitted are respectivelyconfigured for each RFID reader to illuminate particular areas ofinterest to assist in the detection of movement of a portable electronicdevice into, out of, and through those areas of interest.

An overview of the features of the exemplary system for detectingdirection of movement of a portable electronic device will now beprovided. The examples of FIGS. 1A-1E illustrate movement of theportable electronic device between time 1 (represented in FIG. 1A), time2 (represented in FIG. 1B), time 3 (represented in FIG. 1C), time 4(represented in FIG. 1D), and time 5 (represented in FIG. 1E). As shownin FIG. 1A, the portable electronic device is closer to RFID reader 110than RFID reader 120 in District 1 at time 1. As shown in FIG. 1B, theportable electronic device has moved away from RFID reader 110 closer toRFID reader 120 at time 2. Reader 110 is closer to the doorway ofdistrict 1, while reader 120 is on the far wall of district 1. Reader110 is arranged in a first location in district 1 (i.e., at the lowerwall of district 1 near the doorway to district 1), while reader 120 isarranged in a second location in district 1 (i.e., on the far wall ofdistrict 1). As illustrated in FIGS. 1A-1E, RFID readers 110 and 120 arearranged at different locations in district 1, RFID readers 142, 144,146 and 148 are arranged at different locations in District 2, RFIDreaders 152, 154 and 156 are arranged at different locations in District3, RFID readers 162 and 164 are arranged at different locations inDistrict 4, and RFID readers 172, 172, 176, 178 and 180 are arranged atdifferent locations in District H.

As shown in FIG. 1C, the portable electronic device has moved away fromRFID reader 120 back toward RFID reader 110, closer to the doorway ofDistrict 1 than in FIG. 1A. As shown in FIG. 1D, the portable electronicdevice has moved out of District 1 into District H, in close proximityto RFID readers 172, 176 and 178. As shown in FIG. 1E, the portableelectronic device has moved farther down the hallway toward Districts 2and 4.

The controller 130 of the exemplary system is configured to determinethe direction of movement of the portable electronic device when theportable electronic device moves between two or more districts. Forinstance, in the following example, the controller is described asdetermining the direction of movement of the portable electronic devicebetween time 1 (FIG. 1A) and time 2 (FIG. 1B).

In the example of FIGS. 1A and 1B, RFID reader 110 can be considered afirst RFID reader, and RFID reader 120 can be considered a second RFIDreader. In the illustrated example, the first RFID reader 110, which isarranged in a first location (i.e., the lower wall of district 1 in FIG.1), is configured to transmit a first location signal 112 from the firstlocation, and to receive a first response signal 114 from the portableelectronic device when the portable electronic device is within range ofthe first location to receive the first location signal 112. The secondRFID reader 120, which is arranged in a second location distinct fromthe first location (i.e., the far wall of District 1), is configured totransmit a second location signal 122 from the second location, and toreceive a second response signal 124 from the portable electronic devicewhen the portable electronic device is within range of the secondlocation to receive the second location signal 122. According to anexemplary embodiment, the portable electronic device is configured totransmit different response signals 114, 124 to the different RFIDreaders 110, 120 because the response signals 114, 124 are individuallyresponsive to the different location signals 112, 122, respectively.Similarly, as shown in FIG. 1D, for example, the portable electronicdevice transmits response signal 173R to RFID reader 172 when theportable electronic device is within range of the location of the RFIDreader 172 (i.e., within the coverage area 173 of the RFID reader 172).In FIG. 1D, the portable electronic device transmits response signal177R to RFID reader 176 upon receiving the location signal from RFIDreader 176. In the example of FIG. 1D, the portable electronic device isalso illustrated as transmitting response signal 114 to RFID reader 110,because the portable electronic device still receives the locationsignal 112 from RFID reader 110. In FIG. 1E, the portable electronicdevice transmits response signal 179R to RFID reader 178 upon receivingthe location signal from RFID reader 178 (i.e., when the portableelectronic device is within the coverage area 179 of RFID reader 178).

Returning to the example of movement of the portable electronic devicebetween FIG. 1A (time 1) and FIG. 1B (time 2), the controller 130 isconfigured to determine whether the first and second response signals114, 124 received by the first and second RFID readers 110, 120respectively satisfy a predetermined condition (e.g., threshold of powerrespectively present in the first and second response signals, ReceivedSignal Strength Indication (RSSI) in the first and second responsesignals, etc.) at the first time (FIG. 1A) and the second time (FIG. 1B)subsequent to the first time. Examples of the above-describedpredetermined condition will be described below. In addition, thecontroller 130 is configured to determine a direction of movement of theportable electronic device relative to the first and second locations(i.e., the location of the RFID readers 110, 120 in the above example)during the first and second times based on whether the first and secondresponse signals 114, 124 respectively satisfy the predeterminedcondition at the first and second times. As will be described in moredetail below with reference to FIG. 4, the controller 130 includes ahardware processor 414 that, by executing a computer program and/orcomputer-readable instructions tangibly recorded on the memory 412,which is a non-transitory computer-readable recording medium (e.g., aROM, hard-disk drive, solid-state drive, flash memory, optical memory,etc.), carries out the operative functions of the controller 130 asdescribed herein.

In accordance with an exemplary embodiment, the above-describedpredetermined condition can be a threshold of power present in the firstand second response signals 114, 124 respectively received by the firstand second RFID readers 110, 120. As noted above, the power of a signalis relative to the amplitude of the signal, i.e. the amplitude of theelectromagnetic wave. In this example, the controller 130 is configuredto determine whether the portable electronic device is present in thefirst location at the first and second times based on the power presentin the first response signal 114 received by the first RFID reader 110at the first and second times, respectively. In addition, the controller130 is configured to determine whether the portable electronic device ispresent in the second location at the first and second times based onthe power present in the second response signal 124 received by thesecond RFID reader 120 at the first and second times, respectively.

According to an exemplary embodiment, the controller 130 is configuredto determine the direction of movement of the portable electronic devicePED relative to the first and second locations by (a) comparing therespective powers present in the first and second response signals 114,124 at the first time relative to the respective powers present in thefirst and second response signals 114, 124 at the second time, and (b)determining the direction of movement of the portable electronic device(PED) relative to the first and second locations based on the comparisonof the respective powers present in the first and second responsesignals 114, 124 at the first and second times.

The above-described features will be explained with reference to theexamples of FIGS. 1A-1E. FIG. 5 is a chart showing the respective powersof response signals transmitted by the portable electronic device toRFID readers in the exemplary system during times 1-5 illustrated inFIGS. 1A-1E, respectively. For clarity of illustration, the respectivepowers of the response signals are described in FIG. 5 as numerical RSSIvalues. As shown in FIG. 3, which will be described in more detailbelow, RFID readers 110 and 120 each respectively include a powermeasurement unit 312, 322, and a control unit 316, 326, which includes amemory 317, 327 and a hardware processor 318, 328. The other RFIDreaders in the exemplary system 100 of FIGS. 1A-1E have correspondingconstituent elements. The power measurement units 312, 322 measure thepower (i.e., amplitude) present in a received response signal, and theprocessors 318, 328 convert the measured power into a numerical RSSIvalue that ranges, for example, from 0 to 100, where 0 means no power,and 100 is the highest possible level of power that is expected to bereceived. FIG. 5 illustrates the RSSI power values of the responsesignals received in the examples of FIGS. 1A-1E.

As shown in FIG. 5, at time 1, the power of the response signal receivedby RFID reader 110 exceeds the power of the response signal received byRFID reader 120 at time 1. However, at time 2, the power of the responsesignal received by RFID reader 110 is less than the power of theresponse signal received by RFID reader. Based on these comparativevalues, the controller 130 determines that, between time 1 and time 2,the portable electronic device has moved away from RFID reader 110toward RFID reader 120, since the power of the response signals receivedby RFID reader 110 decreased between time 1 and time 2, and the power ofthe response signals received by RFID 120 increased between time 1 and2. Conversely, between time 2 and time 3, the controller 130 determines,based on the power levels at times 1-3, that the portable electronicdevice has moved away from RFID reader 120 back toward RFID reader 110,since the power of the response signals received by RFID reader 110increased between time 2 and time 3, and the power of the responsesignals received by RFID reader 120 decreased between time 2 and time 3.The controller 130 similarly analyzes the level of power present in theresponse signals for times 4 and 5.

Accordingly, with reference to the examples of FIGS. 1A and 1B, thecontroller 130 is configured to determine whether the portableelectronic device is closer to the first location (i.e., the location ofRFID reader 110) or the second location (i.e., the location of RFIDreader 120) at the first time (time 1) by (a) comparing the powerpresent in the first response signal 114 to the power present in thesecond response signal 124 at the first time, (b) determining that theportable electronic device is closer to the first location at the firsttime when the power present in the first response signal 114 is greaterthan the power present in the second response signal 124 at the firsttime, and (c) determining that the portable electronic device PED iscloser to the second location at the first time when the power presentin the second response signal 124 is greater than the power present inthe first response signal 114 at the first time. Further, with continuedreference to the examples of FIGS. 1A and 1B, the controller 130 isconfigured to determine whether the portable electronic device is closerto the first location or the second location at the second time (time 2)by (d) comparing the power present in the first response signal 114 tothe power present in the second response signal 124 at the second time,(e) determining that the portable electronic device is closer to thefirst location at the second time when the power present in the firstresponse signal 114 is greater than the power present in the secondresponse signal 124 at the second time, and (f) determining that theportable electronic device is closer to the second location at thesecond time when the power present in the second response signal 124 isgreater than the power present in the first response signal 114 at thesecond time.

In accordance with the above-described examples of FIGS. 1A and 1B, thecontroller 130 is configured to determine the direction of movement ofthe portable electronic device by (a) determining whether the portableelectronic device is closer to the first location (i.e., the location ofRFID reader 110) or the second location (i.e., the location of RFIDreader 120) at the first time, (b) determining whether the portableelectronic device is closer to the first location or the second locationand the second time, and (c) deriving the direction of movement of theportable electronic device based on the determinations of whether theportable electronic device is closer to the first location or the secondlocation at the first and second times, respectively.

FIG. 3 is a block diagram illustrating the hardware architectures ofRFID readers in a district of the system of FIGS. 1A-1E, in accordancewith an exemplary embodiment. The hardware architectures of RFID readers110 and 120 are provided as examples. The other RFID readers 110 and 120can have similar constituent components. As illustrated in FIG. 3, theRFID readers 110 and 120 respectively include a power measurement unit312, 322, an antenna 314, 324, a control unit 316, 326 having anon-transitory computer-readable recording memory 317, 318, a hardwareprocessor 318, 328, and a transceiver 319, 329, respectively. Theantenna 314, 324 of the RFID readers transmit the above-describedlocation signals to the respective coverage area of the RFID reader andreceive a corresponding location signal when the portable electronicdevice is within range of the RFID reader to receive the location signalfor a particular coverage area (e.g., when the portable electronicdevice is within the coverage area of RFID reader 110 to receivelocation signal 112 to transmit the response signal 114 to RFID reader110). The respective power measurement units 312, 322 are configured tomeasure the amount of power present in the response signal received bythe corresponding RFID reader. For example, with reference to FIG. 1A,power measurement unit 312 of RFID reader 110 is configured to measurethe amount of power present in the response signal 114 received from theportable electronic device when the portable electronic device is withinrange of the location of RFID reader 110 to receive the location signal112. Similarly, power measurement unit 322 of RFID reader 120 isconfigured to measure the amount of power present in the response signal124 received from the portable electronic device when the portableelectronic device is within range of the location of the RFID reader 120to receive the location signal 122.

The control units 316, 326 of the RFID readers 110, 120 each include anon-transitory computer readable recording medium as tangible memories317, 327, and hardware processors 318, 328 for carrying out theoperative functions of the RFID readers. As discussed above, a hardwareprocessor device as discussed herein may be a single hardware processor,a plurality of hardware processors, or combinations thereof. Hardwareprocessor devices may have one or more processor “cores.” The hardwareprocessors 318, 328 execute an operating system and computer programstangibly recorded on the memories 317, 327. The memories 317, 327 mayalso store a control policy to control operations of the portableelectronic device based on the detected location and movement of theportable electronic device. For example, the control policy mayauthorize or prevent the portable electronic device from accessingcertain hardware resources such as the camera 216, microphone 218 orinterfaces 222 or 228 when the portable electronic device is detected tobe in a particular District (e.g., District 1), when the portableelectronic device is detected to move in a particular pattern (e.g.,leave District 1 but return to District 1 within a predetermined time),and/or when the portable electronic device has been in a particulardistrict for a predetermined period of time.

According to the above-described exemplary embodiment, the first RFIDreader 110 includes a first power measurement unit 310 configured tomeasure power present in the first response signal 114 received by thefirst RFID reader 110, a first control unit 316 configured to generate afirst RSSI signal indicating the measured power in the first responsesignal 114, and a first transceiver 319 configured to transmit the firstRSSI signal to the controller 130 when the first RFID reader 110receives the first response signal 114. The second RFID reader 120includes a second power measurement unit configured to measure power inthe second response signal 124 received by the second RFID reader 120, asecond control unit 326 configured to generate a second RSSI signalindicating the measured power in the second response signal 124, and asecond transceiver 329 configured to transmit the second RSSI signal tothe controller 130 when the second RFID reader 120 receives the secondresponse signal 124. According to the above-described exemplaryembodiments illustrated in FIGS. 1A-1E and 3-5, the controller 130 isconfigured to determine an amount of power present in the first responsesignal 114 based on the first RSSI signal received from the first RFIDreader 110, and to determine an amount of power present in the secondresponse signal 124 based on the second RSSI signal received from thesecond RFID reader 120.

According to the exemplary embodiments of FIGS. 1A-1E and 3-5, theabove-described predetermined condition can be a threshold value of theamount of power present in the first and second response signals 114,124 respectively received by the first and second RFID readers 110, 120.The controller 130 is configured to determine whether the portableelectronic device is present in the first location at the first andsecond times based on the power present in the first response signal 114received by the first RFID reader 110 at the first and second times,respectively. Further, the controller 130 is configured to determinewhether the portable electronic device is present in the second locationat the first and second times based on the power present in the secondresponse signal 124 received by the second RFID reader 120 at the firstand second times, respectively. For example, the controller 130 isconfigured to determine the direction of movement of the portableelectronic device relative to the first and second locations bycomparing the respective powers present in the first and second responsesignals 114, 124 at the first time relative to the respective powerspresent in the first and second response signals 114, 124 at the secondtime, and determining the direction of movement of the portableelectronic device relative to the first and second locations based onthe comparison of the respective powers present in the first and secondresponse signals 114, 124 at the first and second times.

According to the exemplary embodiments of FIGS. 1A-1E and 3-5, thecontroller 130 is configured to determine whether the portableelectronic device is closer to the first location or the second locationat the first time by (a) comparing the power present in the firstresponse signal to the power present in the second response signal atthe first time (see FIG. 5), (b) determining that the portableelectronic device is closer to the first location at the first time whenthe power present in the first response signal 114 is greater than thepower present in the second response signal 124 at the first time, anddetermining that the portable electronic device is closer to the secondlocation at the first time when the power present in the second responsesignal 124 is greater than the power present in the first responsesignal 114 at the first time. In addition, the controller 130 isconfigured to determine whether the portable electronic device PED iscloser to the first location or the second location at the second timeby (d) comparing the power present in the first response signal 114 tothe power present in the second response signal 124 at the second time,(e) determining that the portable electronic device is closer to thefirst location at the second time when the power present in the firstresponse signal 114 is greater than the power present in the secondresponse signal 124 at the second time, and (f) determining that theportable electronic device is closer to the second location at thesecond time when the power present in the second response signal 124 isgreater than the power present in the first response signal 114 at thesecond time.

In accordance with the above-described embodiments, the controller 130is configured to determine the direction of movement of the portableelectronic device by (a) determining whether the portable electronicdevice is closer to the first location or the second location at thefirst time, (b) determining whether the portable electronic device iscloser to the first location or the second location and the second time,and (c) deriving the direction of movement of the portable electronicdevice based on the determinations of whether the portable electronicdevice is closer to the first location or the second location at thefirst and second times, respectively.

FIGS. 6-9 provide another illustrative example of the functionality ofthe RFID readers and the controller in the exemplary system of thepresent disclosure. FIG. 6 is a diagram of an exemplary system forillustrating the detection of movement of a portable electronic devicebetween two RFID readers in different coverage areas. In FIG. 6, tworeaders (Reader 1 and Reader 2) are arranged on opposite sides of aboundary (e.g., doorway) between two districts. In this example, thereaders have coverage areas as shown in FIG. 6, where the vertical planeof the door defines the location x=0 as an RFID component (e.g., RFIDtag) of a portable electronic device moves from district to district. Inthis example, Reader 1 is arranged in the ceiling at x=−1, and Reader 2is arranged in the ceiling at x=1.

As the RFID tag in the portable electronic device is moved from thedistrict of Reader 1, for example from x=−3, through the doorway, tox=+3, the power of the response signal from the tag measured at Reader 1will vary as shown in FIG. 7A. Likewise, as the RFID tag in the portableelectronic device is moved from the district of Reader 2, for examplefrom x=−3, through the doorway to x=+3, the power of the response signalfrom the tag measured at Reader 2 will vary as shown in FIG. 7B.

As the RFID tag in the portable electronic device moves, the derivativeof power with respect to distance is shown in FIGS. 8A and 8B. FIG. 8Ashows the signal power, P, and derivative with distance, P′, versusdistance, x, from Reader 1. FIG. 8B shows the shows the signal power, P,and derivative with distance, P′, versus distance, x, from Reader 2.

If the RFID tag in the portable electronic device is moving in time,then the position x is a function of time, x(t). Therefore, the powermeasured by the readers as a function of time are, P1(x1(t)) andP2(x2(t), where x1 is the distance from reader 1, and x2 is the distancefrom reader 2. Using a calculus identity, the derivative of power withrespect to time measured by each reader is:dP1/dt=dP1/dx1*dx1/dt and dP2/dt=dP2/dx2*dx2/dt.If the velocity of the tag moving from one district to another districtis a relative constant, v, then the relative power and derivative ofpower with respect to time measured by each reader is:P1(t)=P1(v*t+1),P2(v*t−1),dP1/dt=dP1/dx1*v,dP2/dt=dP2/dx2*v.FIG. 9 shows the reader signals and time derivatives for constantvelocity motion from the district in which Reader 1 is arranged(referred to as “district 1” below) to the district in which Reader 2 isarranged (referred to as “district 2” below).

Based on the above, the processor 414 of the controller 130 isconfigured to execute an algorithmic computer program, which is storedin the non-transitory memory 412, to determine RFID tag motion fromdistrict 1 to district 2, for an RFID tag moving from district 1 todistrict 2 at a relatively constant velocity, by measuring the powerwith respect to time and the first derivative, with the followingalgorithmic parameters:

1) Both readers sample the RSSI power periodically in time. Based on thesampling, the derivative of dP/dt is calculated. Assume a tag approachesthe district boundary from the region of district 1 (e.g., from theregion to the left of the graphs in FIGS. 7A-9).

2) Initially, the signal and derivative of reader1 will increase(event1).

3) As the RFID tag moves closer to the boundary between district 1 anddistrict 2 (x=0), the derivative of the signal at reader 1 will gothrough a maximum and then pass through zero, the zero passing being aneasily detectable event (event 2).

4) As the RFID tag continues to move closer to the boundary (x=0), thederivative of the signal at reader 1 will begin to decrease less thanzero, and the signal and time derivative at reader 2 will increase(event3).

5) As the RFID tag moves to the district 2 side of the boundary (x=0),the time derivative of the signal at reader 2 will pass through zero,and the signal at reader 2 will be at a maximum (event 4).

6) As the RFID tag continues to move into district 2, the derivative ofthe signal at reader 2 will pass through zero becoming less than zero,and the signal at reader 2 will decrease (event 5).

7) After event 5, when the signal from the RFID tag drops to apredetermined level relative to the maximum signal received at reader 2(e.g., less than 50%), then the tag will be provisioned by thecontroller 130 for operation in district 2 (event 6). A valid motionfrom district 1 to district 2 will be when events 1 through 6 occur inorder. According to an exemplary embodiment, the controller 130 may beconfigured to detect when the RFID tag of the portable electronic deviceis within a certain distance from a particular RFID reader based on thepower of the response signal (e.g., RSSI value) received by that RFIDreader. For example, with reference to FIG. 1D, the controller 130 maybe configured, with calibration, to determine that the portableelectronic device is in District H when the RSSI value of the responsesignal 177R received by RFID reader 176 is 50 or above. In this example,an RSSI value of 50 or above indicates that the portable electronicdevice is approximately 5 meters from the RFID reader 176. Since thecoverage area 177 of the RFID reader 176 includes the area of District Hnear the doorway to District 1 in FIGS. 1A-1E, the controller 130 may beconfigured to determine, in accordance with events 1-5 as discussedabove, that the portable electronic device has moved from District 1 attimes 1-3 to District H at time 4 because the power of the responsesignal 177R received by RFID reader 176 at time 4 represents that theportable electronic device is approximately 5 meters from RFID reader176 at time 4 and has therefore moved from District 1 at times 1-3 toDistrict H at time 4.

The controller 130 is also configured to make other determinations basedon the movement of the RFID tag of the portable electronic device andthe resultant response signals received by the RFID readers. Forexample, if the RFID tag stops, there will be discontinuity in eitherreader's dP/dt, (e.g. dP/dt suddenly goes to zero), or if the RFIDreverses motion, in which case there will be discontinuity and a signchange of both reader's dP/dt. In this way, the controller 130continuously validates whether the portable electronic device enters,leaves or remains in a particular district or area over a period of time(e.g., times 1-5 as illustrated in FIGS. 1A-1E). It is to be understoodthat FIGS. 1A-1E are intended to be examples, and the controller 130 cancontinuously validate whether the portable electronic device (ormultiple portable electronic devices) enter, leave or remain in aparticular district or area over any period of time.

Referring back to the example of FIGS. 1A-1E, at least one of the firstRFID reader 110 and the second RFID reader 120 comprises an ellipticalor circularly polarized antenna such that at least one of the first RFIDreader 110 and the second RFID reader 120 respectively transmits thecorresponding one of the first location signal 112 and the secondlocation signal 122 in orthogonal polarizations in the correspondingfirst and second locations, respectively.

According to the exemplary system 100 in FIGS. 1A-1E, the first RFIDreader (e.g., RFID reader 110) is arranged on a first side of a room ofa building, and the second RFID reader (e.g., RFID reader 120) isarranged on a second side of the room distinct from the first side ofthe room. According to another example, the first RFID reader isarranged in a room of a building (e.g., RFID reader 110), and the secondRFID reader (e.g., RFID reader 176) is arranged in a hallway outside theroom of the building. In this example, the controller 130 is configuredto determine whether the portable electronic device is transported fromthe hallway into the room, and whether the portable electronic device istransported from the room into the hallway.

Exemplary embodiments of the present disclosure were described abovewith respect to an example of first and second RFID readers (e.g., RFIDreaders 110 and 120). The present disclosure is not limited to thisexample. As illustrated in FIGS. 1A-1E, the exemplary system 100 caninclude three or more RFID readers. For example, the exemplary system100, in addition to RFID readers 110 and 120, can include a third RFIDreader (e.g., any one of readers 172, 176, 178 and 180 in FIGS. 1A-1E)arranged in the hallway at a third location distinct from the first andsecond locations. The third RFID reader (e.g., RFID reader 176) isconfigured to transmit a third location signal (e.g., location signal177) from the third location, and to receive a third response signal(e.g., response signal 177R illustrated in FIG. 1D) from the portableelectronic device when the portable electronic device is within range ofthe third location to receive the third location signal 177. Inaddition, in this example, the controller 130 is configured to determinewhether the portable electronic device is closer to one of the firstRFID reader 110, the second RFID reader 120 and the third RFID reader(e.g., RFID reader 176) at the first and second times, respectively,based on an amount of power respectively present in the first responsesignal 114 received by the first RFID reader 110, the second responsesignal 124 received by the second RFID reader 120, and the thirdresponse signal received by the third RFID reader (e.g., RFID reader176) at the first and second times, respectively.

In accordance with the above-described exemplary embodiment, thecontroller 130 is configured to compare the amount of power respectivelypresent in the first response signal 114 received by the first RFIDreader 110, the second response signal 124 received by the second RFIDreader 120, and the third response signal received by the third RFIDreader (e.g., RFID reader 176) at the first and second times,respectively, and to determine whether the portable electronic device iscloser to one of the first RFID reader 110, the second RFID reader 120and the third RFID reader (e.g., RFID reader 176) at the first andsecond times based on which one of the first response signal 114, thesecond response signal 124 and the third response signal has thegreatest amount of power at the first and second times, respectively.

As illustrated in FIGS. 1A-1E, in the exemplary system 100 of thepresent disclosure, the first RFID reader (e.g., RFID reader 110) isarranged in a first district of a building, and the second RFID reader(e.g., any of the readers not in district 1 in FIGS. 1A-1E) is arrangedin a second district of the building distinct from the first district.In accordance with this embodiment, the first district is a room in thebuilding, and the second district is a hallway outside the room.Further, as described above, the first district may be located on adifferent floor of the building than the second district.

In accordance with an exemplary embodiment, the controller 130 isconfigured to determine an amount of time that the portable electronicdevice is present in at least one of the first and second locations(e.g., locations of RFID readers 110, 120) based on the first and secondresponse signals 114, 124 over a period of time.

According to an exemplary embodiment, the controller 130 is configuredto control the first RFID reader (e.g., RFID reader 110) to transmit afirst authorization signal to the portable electronic device when thefirst RFID reader (e.g., RFID reader 110) receives the first responsesignal 114 from the portable electronic device. The first authorizationsignal authorizes the portable electronic device to execute a first setof operations while the portable electronic device receives the firstlocation signal. For example, the first authorization signal canauthorize the portable electronic device to have access to certain dataor to have access to hardware components of the portable electronicdevice (e.g., camera) or external hardware components while the portableelectronic device is present in the first location and receives thefirst location signal. In addition, the controller 130 is configured tocontrol the second RFID reader 120 to transmit a second authorizationsignal to the portable electronic device when the second RFID reader 120receives the second response signal 124 from the portable electronicdevice. Similar to the first authorization signal, the secondauthorization signal authorizes the portable electronic device toexecute a second set of operations (e.g., access data and/or hardwarecomponents) while the portable electronic device receives the secondlocation signal. This authorization procedure in two different locationsfacilitates authorization of distinct operations of the portableelectronic device when the portable electronic device moves from onelocation to another. For example, suppose the building illustrated inFIGS. 1A-1E is a hospital or other medical building, where Districts 1-4are patient rooms, and District H is the hallway. In accordance with theabove-described embodiment, the controller 130 can control the firstRFID reader 110 to transmit a first authorization signal when the firstRFID reader 110 receives the first response signal 114 from the portableelectronic device, after the RFID reader 176 stops receiving theresponse signal 177R, consistent with the portable electronic devicebeing moved from the hallway (District H) into the patient room (e.g.,District 1). In this way, the controller 130 can authorize a medicalprofessional transporting the portable electronic device to have accessto a particular patient's medical records on the portable electronicdevice when the portable electronic device is detected to move into andbe present in District 1. When the medical professional carrying theportable electronic device leaves District 1 and returns to District H,the portable electronic device will receive a location signal (as wellas an authorization signal) from RFID reader(s) in District H (e.g.,location signal 177 from RFID reader 176) but will no longer receive anauthorization signal from the RFID reader(s) in District 1, in whichcase the portable electronic device will then not be authorized toaccess (or continue to access) the medical records of the patient inDistrict 1. Similarly, the controller 130, by sending such authorizationsignal(s) to the portable electronic device when it is detected to belocated in a particular district or area, can enable/disable theportable electronic device to have access to certain data or access tohardware components of the portable electronic device (e.g., camera) orexternal hardware components while the portable electronic device ispresent in that district and receives an authorization signal while inthat district.

According to an exemplary embodiment, the controller 130 is configuredto modify at least one of the first set of operations and the second setof operations, such as the first and second sets of operations asdescribed above. According to an exemplary embodiment, the first RFIDreader (e.g., RFID reader 110) transmits the first location signal(e.g., location signal 112) at a first frequency, and the second RFIDreader (e.g., RFID reader 120) transmits the second location signal at asecond frequency different from the first frequency. The controller 130is configured to control the first RFID reader (e.g., RFID reader 110)to transmit a first authorization signal to the portable electronicdevice when the first RFID reader (e.g., RFID reader 110) receives thefirst response signal 114 from the portable electronic device at thefirst frequency including any predetermined tolerance range (e.g., +/−1%of the first frequency), or at a predetermined percentage range of thefirst frequency (e.g., 89-91% of the first frequency). The firstauthorization signal authorizes the portable electronic device toexecute a first set of operations while the portable electronic devicereceives the first location signal 112, as described above. Similarly,the controller 130 is configured to control the second RFID reader(e.g., RFID reader 120) to transmit a second authorization signal to theportable electronic device when the second RFID reader (e.g., RFIDreader 120) receives the second response signal 124 from the portableelectronic device at the second frequency including any predeterminedtolerance range (e.g., +/−1% of the second frequency), or at apredetermined percentage range of the second frequency (e.g., 89-91% ofthe second frequency). The second authorization signal authorizes theportable electronic device to execute a second set of operations whilethe portable electronic device receives the second location signal.According to an exemplary embodiment, the controller 130 is configuredto control the first and second RFID readers (e.g., RFID readers 110,120) to respectively change the first and second frequencies at apredetermined time. Changing the respective frequencies can serve avariety of purposes such as improving security and avoiding interferencein the system.

According to an exemplary embodiment, the RFID readers of the exemplarysystem 100 are configured to operate in the 900 MHz ISM frequency space.For instance, the North American ISM band is 902-928 MHz. In thisexample, the RFID readers are configured to operate in this band forregulatory reasons. However, it is to be understood that the RFIDreaders can be configured to operate in other frequency ranges. Theportable electronic device of the present disclosure includes an RFIDcomponent (e.g., RFID tag) that communicates with the RFID readers inthe frequency band in which the RFID readers are configured to operate.For example, the RFID component of the portable electronic device canoperate in a frequency range between 860 and 960 MHz. The sensitivity ofthe antenna of the RFID component is important to the operation of theRFID component, and a minimum receive gain of the antenna greater than−2 dB should be maintained to ensure proper operation. In accordancewith an exemplary embodiment, the antenna(s) of the RFID component ofthe portable electronic device provide(s) a roughly omni-directionalradiation pattern. Due to regional banding of the ˜900 MHz ISM frequencyspace, the antenna(s) may be regionally designed. For instance, theNorth American ISM band is 902-928 MHz. With a transmitter at 28 dBmcomplying with FCC and UHF RFID Gen2 Specifications, this should yield afree space range of approximately 20 meters.

According to an exemplary embodiment, the RFID component can beremovably or permanently affixed to the portable electronic device. FIG.2 is a block diagram illustrating the hardware architecture of aportable electronic device 200 in accordance with an exemplaryembodiment. In the example of FIG. 2, the RFID component 210 isillustrated as being comprised within the housing containing theelectronic circuitry of the portable electronic device 200. Inaccordance with an exemplary embodiment, the RFID component 210 may haveits own hardware processor 214 separate from the hardware processor(s)of the portable electronic device 200. In addition, the RFID component210 has its own non-transitory memory 212 (e.g., ROM, hard disk drive,optical memory, flash memory, etc.) separate from the memory 208 of theportable electronic device 200, and a transceiver 220. In an exemplaryembodiment, the RFID component 210 does not have its own hardwareprocessor 214, but contains the memory 212 and the transceiver 220. TheRFID component 210 may be passive, active, or battery-assisted passive.An active RFID component 210 has an on-board battery and periodicallytransmits a signal containing a data message (the message can include,e.g., identification information of the RFID component, etc.). Abattery-assisted passive RFID component 210 has a small battery on boardand is activated when in the presence of an RFID reader 100. A passiveRFID component 210 is cheaper and smaller because it has no battery;instead, the RFID component 210 uses the radio energy transmitted by theRFID reader 100. The RFID component 210 contains at least two parts: anintegrated circuit for storing and processing information, modulatingand demodulating a radio-frequency (RF) signal, collecting DC power fromthe incident reader signal, and other specialized functions; and atransceiver 220 (e.g., antenna) for receiving and transmitting thesignal. In an exemplary embodiment, the transceiver 220 can include twoantennas in different polarizations such as linear and circular orhorizontal and vertical. A single antenna can also be used.

According to an exemplary embodiment, the RFID component 210 can beconfigured to store RFID component information (i.e. tag information) ina non-volatile memory, e.g., memory 212. The RFID component 210 includeseither fixed or programmable logic for processing the transmission andsensor data, respectively. In an exemplary embodiment, the RFIDcomponent 210 includes an Impinj MonzaX-8K Dura RFID integrated circuitor similar integrated circuit. As will be described in more detailbelow, the RFID component 210 of the portable electronic device can beconfigured to transmit a response signal to an RFID reader in theexemplary system 100 when the portable electronic device is within rangeof the location of the RFID reader to receive the location signal fromthat RFID reader. In accordance with an exemplary embodiment, the RFIDcomponent 210 of the portable electronic device can be configured totransmit, with its response signal, the component information of theRFID component 210 to the RFID reader from which the RFID component 210received the location signal. The RFID reader that receives the RFIDcomponent information from the portable electronic device can then, inturn, store the received RFID component information in its memory (seeFIG. 3) and transmit it to the controller 130.

With continued reference to FIG. 2, hardware processor 204 of theportable electronic device may be a special purpose or a general-purposeprocessor device. Hardware processor 214 may be a special purpose or ageneral-purpose processor device. The hardware processor device 204 maybe connected to a communication infrastructure 206, such as a bus,message queue, network, multi-core message-passing scheme, etc. Thenetwork may be any network suitable for performing the functions asdisclosed herein and may include a local area network (LAN), a wide areanetwork (WAN), a wireless network (e.g., Wi-Fi), a mobile communicationnetwork, a satellite network, the Internet, fiber optic, coaxial cable,infrared, radio frequency (RF), or any combination thereof. Othersuitable network types and configurations will be apparent to personshaving skill in the relevant art. The portable electronic device 200 mayalso include a memory 208 (e.g., random access memory, read-only memory,etc.), and may also include a memory 212. The memory 208 and the memory212 may be read from and/or written to in a well-known manner. Inaccordance with an exemplary embodiment, the memory 208 and the memory212 (and memories 317 and 327 of the RFID readers in FIG. 3) arenon-transitory computer readable recording media (e.g., ROM, hard diskdrive, flash memory, optical memory, solid-state drive, etc.). Ahardware processor device as discussed herein may be a single hardwareprocessor, a plurality of hardware processors, or combinations thereof.Hardware processor devices may have one or more processor “cores.”

Data stored in the portable electronic device 200 (e.g., in the memory208 and the memory 212) may be stored on any type of suitable computerreadable media, such as optical storage (e.g., a compact disc, digitalversatile disc, Blu-ray disc, etc.), magnetic tape storage (e.g., a harddisk drive), or solid-state drive. An operating system 232, one or moreapplications 234, and one or more hypervisors 236 can be stored in thememory 208.

The portable electronic device 200 may also include a communicationsinterface 224. The communications interface 224 may be configured toallow software and data to be transferred between the portableelectronic device 200 and external devices. Exemplary communicationsinterfaces 224 may include a wireless modem (e.g., transceiver), anetwork interface (e.g., an Ethernet card), a communications port, aPCMCIA slot and card, etc. Software and data may be transferred via thecommunications interface 224 to external devices.

The memories 208 and 212, which are non-transitory computer-readablerecording media, may store operating systems and/or computer programs tobe executed by the portable electronic device 200. Computer programs mayalso be received via the communications interface 224. Such computerprograms, when executed, may enable the portable electronic device 200to implement its operative functions that may be controlled, asdiscussed herein, based on the detected location of the portableelectronic device. For instance, the operating system and/or computerprograms, when executed, may enable hardware processor device 204 toaccess or operate hardware components such as the camera 216, themicrophone 218, the peripheral interface 222, theUSB/Firewire/Thunderbolt interface ports 228, and/or the display 230(e.g., LED screen, touch screen, etc.).

In accordance with the examples of FIGS. 1A and 1B, an exemplaryembodiment of the present disclosure provides the system in combinationwith a portable electronic device, wherein the portable electronicdevice comprises an RFID tag (210 in FIG. 2) configured to transmit thefirst response signal 114 when the portable electronic device is withinrange of the first location to receive the first location signal 112,and to transmit the second response signal 124 when the portableelectronic device is within range of the second location to receive thesecond location signal 122. According to an exemplary embodiment, theRFID tag 210 is a passive tag configured to transmit the first responsesignal 114 in response to receiving the first location signal 112 whenthe portable electronic device is within range of the first location toreceive the first location signal 112, and to transmit the secondresponse signal 124 in response to receiving the second location signal122 when the portable electronic device is within range of the secondlocation to receive the second location signal 122.

In accordance with an exemplary embodiment, the RFID tag comprises aunique identifier (e.g., an electronic product code (EPC) or tag ID(TID) of the RFID component or other uniquely assigned identifier). TheRFID tag is configured to transmit the first response signal 114 to thefirst RFID reader 110 by modulating the first location signal 112 withthe unique identifier of the RFID tag and transmitting the modulatedfirst location signal with the unique identifier of the RFID tag. Inaddition, the RFID tag is configured to transmit the second responsesignal 124 to the second RFID reader 120 by modulating the secondlocation signal 122 with the unique identifier of the RFID tag andtransmitting the modulated second location signal with the uniqueidentifier of the RFID tag. In this way, the controller 130 candetermine the location of individual portable electronic devices basedon the unique identifier of the RFID tag of the portable electronicdevice. The controller 130 can then authorize or prevent an individualportable electronic device from performing certain operations based onthe motion of the portable electronic device from one district toanother as well as the current location of that portable electronicdevice.

According to an exemplary embodiment, the RFID tag is an active taghaving a unique identifier, and the portable electronic device includesa battery power source configured to supply power to the RFID tag. Inaccordance with this embodiment, the RFID tag is configured to generateand transmit the first response signal 114 to the first RFID reader 110when the portable electronic device is within range of the firstlocation, where the first response signal 114 contains the uniqueidentifier of the RFID tag. In addition, the RFID tag is configured togenerate and transmit the second response signal 124 to the second RFIDreader when the portable electronic device is within range of the secondlocation, where the second response signal 124 contains the uniqueidentifier of the RFID tag. Similar to the above-described embodimentwhere the RFID tag is a passive tag, the controller 130 can authorize orprevent an individual portable electronic device with an active RFID taghaving a unique identifier from performing certain operations based onthe motion of the portable electronic device from one district toanother as well as the current location of that portable electronicdevice and the unique identifier of the RFID tag.

According to an exemplary embodiment, the portable electronic deviceincludes at least one processor 204, 214 and at least one memory 208,212 having recorded thereon operation instructions that the at least oneprocessor 204, 212 executes to perform operations of the portableelectronic device. In accordance with this embodiment, the controller130 is configured to control at least one operation of the portableelectronic device by authorizing or disallowing the at least oneoperation to be executed by the at least one processor 204, 212 of theportable electronic device based on whether (i) the first RFID reader110 receives the first response signal (114) from the portableelectronic device and/or (ii) the second RFID reader 120 receives thesecond response signal 124 from the portable electronic device, asdescribed below in connection with the transmission of authorizationsignals from the RFID readers.

According to an exemplary embodiment, the controller 130 is configuredto control the first RFID reader 110 to transmit a first authorizationsignal to the portable electronic device when the first RFID reader 110receives the first response signal 114 from the portable electronicdevice. The first authorization signal authorizes the at least oneprocessor 204, 212 of the portable electronic device to execute a firstset of operations, as described above. The controller 130 is configuredto control the second RFID reader 120 to transmit a second authorizationsignal to the portable electronic device when the second RFID reader 120receives the second response signal 124 from the portable electronicdevice. The second authorization signal authorizes the at least oneprocessor 204, 212 of the portable electronic device to execute a secondset of operations, which at least partially differ from the first set ofoperations. The at least one processor 204, 212 of the portableelectronic device is configured to execute the first set of operationswhen the RFID tag of the portable electronic device receives the firstauthorization signal. The at least one processor of the portableelectronic device is configured to execute the second set of operationswhen the RFID tag of the portable electronic device receives the secondauthorization signal.

In accordance with the above-described exemplary embodiment, the atleast one processor 204, 212 of the portable electronic device isconfigured to execute the first set of operations while the RFID tag ofthe portable electronic device receives the first authorization signalwhen the portable electronic device is in the first location. Inaddition, the at least one processor 204, 212 of the portable electronicdevice is configured to execute the second set of operations while theRFID tag of the portable electronic device receives the secondauthorization signal when the portable electronic device is in thesecond location.

In accordance with an exemplary embodiment, the at least one processor204, 212 of the portable electronic device is configured to authenticatethe controller 130 when the RFID tag receives the first authorizationsignal, and control the RFID tag to transmit a first authenticationsignal to the controller 130 upon authenticating the controller 130. Inaddition, the at least one processor 204, 212 of the portable electronicdevice is configured to authenticate the controller 130 when the RFIDtag receives the second authorization signal, and control the RFID tagto transmit a second authentication signal to the controller 130 uponauthenticating the controller 130.

An exemplary embodiment of the present disclosure provides a method ofdetecting direction of movement. The features of the above-describedembodiments of the system of the present disclosure can be implementedin the method of the present disclosure. FIG. 10 illustrates a flowdiagram of an exemplary embodiment of the method. In step 1002, a firstRFID reader (e.g., reader 110 in FIGS. 1A-1E) arranged in a firstlocation (e.g., the lower wall in District 1) transmits a first locationsignal (e.g., location signal 112) from the first location. In step1004, a second RFID reader (e.g., reader 176 in FIGS. 1A-1E) arranged ina second location (e.g., far wall in District H) transmits a secondlocation signal (e.g., location signal 177) from the second location. Instep 1006, the first RFID reader receives a first response signal (e.g.,response signal 114 in FIG. 1A) from a portable electronic device (PED)when the portable electronic device is within range of the firstlocation to receive the first location signal transmitted by the firstRFID reader. In step 1008, the second RFID reader receives a secondresponse signal (e.g., response signal 177R in FIG. 1D) from theportable electronic device when the portable electronic device is withinrange of the second location to receive the second location signaltransmitted by the second RFID reader. In step 1010, a hardwareprocessor of a controller (e.g., processor unit 402 of controller 130 inFIG. 4) determines whether the first and second response signalsreceived by the first and second RFID readers respectively satisfy apredetermined condition at a first time and a second time subsequent tothe first time. In step 1012, the hardware processor of the controllerdetermines a direction of movement of the portable electronic devicerelative to the first and second locations during the first and secondtimes based on the determination of whether the first and secondresponse signals respectively satisfy the predetermined condition at thefirst and second times.

In accordance with an exemplary embodiment of the method of the presentdisclosure, the controller includes a transceiver (e.g.,transceiver/interface 406 in FIG. 4) that receives the first responsesignal from the first RFID reader and receives the second responsesignal from the second RFID reader.

In accordance with an exemplary embodiment of the method of the presentdisclosure, the above-described predetermined condition is a thresholdof power present in the first and second response signals respectivelyreceived by the first and second RFID readers. In accordance with thisembodiment, the exemplary method includes determining, by the processorof the controller, whether the portable electronic device is present inthe first location at the first and second times based on the powerpresent in the first response signal received by the first RFID readerat the first and second times, respectively. In addition, the exemplarymethod includes determining, by the processor of the controller, whetherthe portable electronic device is present in the second location at thefirst and second times based on the power present in the second responsesignal received by the second RFID reader at the first and second times,respectively.

In accordance with an exemplary embodiment of the method of the presentdisclosure, the method includes determining, by the processor of thecontroller, the direction of movement of the portable electronic devicerelative to the first and second locations by (i) comparing therespective powers present in the first and second response signals atthe first time relative to the respective powers present in the firstand second response signals at the second time, and (ii) determining thedirection of movement of the portable electronic device relative to thefirst and second locations based on the comparison of the respectivepowers present in the first and second response signals at the first andsecond times.

In accordance with an exemplary embodiment of the method of the presentdisclosure, the first RFID reader, upon receiving the first responsesignal, measures power present in the first response signal received bythe first RFID reader, generates a first received signal strengthindicator (RSSI) signal indicating the measured power in the firstresponse signal, and transmits the first RSSI signal to the controller.In addition, the second RFID reader, upon receiving the second responsesignal, measures power in the second response signal received by thesecond RFID reader, generates a second RSSI signal indicating themeasured power in the second response signal, and transmits the secondRSSI signal to the controller when the second RFID reader receives thesecond response signal. In accordance with this embodiment, theprocessor of the controller determines an amount of power present in thefirst response signal based on the first RSSI signal received from thefirst RFID reader, and determines an amount of power present in thesecond response signal based on the second RSSI signal received from thesecond RFID reader.

In accordance with an exemplary embodiment of the method of the presentdisclosure, the above-described predetermined condition is a thresholdvalue of the amount of power present in the first and second responsesignals respectively received by the first and second RFID readers. Theexemplary method includes determining, by the processor of thecontroller, whether the portable electronic device is present in thefirst location at the first and second times based on the power presentin the first response signal received by the first RFID reader at thefirst and second times, respectively. In addition, the exemplary methodincludes determining, by the processor of the controller, whether theportable electronic device is present in the second location at thefirst and second times based on the power present in the second responsesignal received by the second RFID reader at the first and second times,respectively.

It is to be understood that any of the features of the above-describedsystem of the present disclosure can be performed in the method of thepresent disclosure, and vice versa.

It will be appreciated by those skilled in the art that the presentinvention can be embodied in other specific forms without departing fromthe spirit or essential characteristics thereof. The presently disclosedembodiments are therefore considered in all respects to be illustrativeand not restricted. The scope of the invention is indicated by theappended claims rather than the foregoing description, and all changesthat come within the meaning, range and equivalence thereof are intendedto be embraced in the claims.

What is claimed is:
 1. A system for detecting direction of movement, thesystem comprising: a first radio frequency identification (RFID) readerarranged in a first location, the first RFID reader comprising a firsttransceiver configured to transmit a first location signal from thefirst location and to receive a first response signal from a portableelectronic device when the portable electronic device is within range ofthe first location to receive the first location signal, a first powermeasurement unit configured to measure power present in the firstresponse signal received by the first transceiver of the first RFIDreader, and a first control unit configured to generate a first powersignal indicating the measured power in the first response signalreceived by the first transceiver of the first RFID reader, a secondRFID reader arranged in a second location distinct from the firstlocation, the second RFID reader comprising: a second transceiverconfigured to transmit a second location signal from the second locationand to receive a second response signal from the portable electronicdevice when the portable electronic device is within range of the secondlocation to receive the second location signal, a second powermeasurement unit configured to measure power present in the secondresponse signal received by the second transceiver of the second RFIDreader, and a second control unit configured to generate a second powersignal indicating the measured power in the second response signalreceived by the second transceiver of the second RFID reader; and acontroller configured to determine a direction of movement of theportable electronic device relative to the first and second locationsduring a first time and a second time subsequent to the first time,wherein the first transceiver of the first RFID reader is configured totransmit the first power signal to the controller for first responsesignal at the first time when the first transceiver of the first RFIDreader receives the first response signal at the first time, and totransmit the first power signal to the controller for the first responsesignal at the second time when the first transceiver of the first RFIDreader receives the first response signal at the second time, whereinthe second transceiver of the second RFID reader is configured totransmit the second power signal to the controller for the secondresponse signal at the first time when the second transceiver of thesecond RFID reader receives the second response signal at the firsttime, and to transmit the second power signal to the controller for thesecond response signal at the second time when the second transceiver ofthe second RFID reader receives the second response signal at the secondtime, and wherein the controller is configured to compare a respectiveamount of power indicated in the first and second power signals for thefirst and second response signals respectively received at the first andsecond times, and to determine the direction of movement of the portableelectronic device during the first and second times based on thecomparative amount of power in the first and second power signals forthe first and second response signals respectively received at the firstand second times.
 2. The system of claim 1, wherein the controller isconfigured to determine whether the portable electronic device ispresent in the first location at the first and second times based on thepower indicated in the first power signal for the first response signalreceived by the first RFID reader at the first time, and the powerindicated in the first power signal for the first response signal at thesecond time, and wherein the controller is configured to determinewhether the portable electronic device is present in the second locationat the first and second times based on the power indicated in the secondpower signal for the second response signal received by the second RFIDreader at the first time, and the power indicated in the second powersignal for the second response signal at the second time.
 3. The systemof claim 2, wherein the controller is configured to determine thedirection of movement of the portable electronic device relative to thefirst and second locations by comparing the respective powers present inthe first and second power signals for the first and second responsesignals at the second time relative to the respective powers present inthe first and second power signals for the first and second responsesignals at the second time, and determine the direction of movement ofthe portable electronic device relative to the first and secondlocations based on the comparison of the respective powers present inthe first and second power signals at the first and second times.
 4. Thesystem of claim 3, wherein the controller is configured to: determinewhether the portable electronic device is closer to the first locationor the second location at the first time by comparing the power presentin the first power signal for the first response signal at the firsttime to the power present in the second power signal for the secondresponse signal at the first time, determining that the portableelectronic device is closer to the first location at the first time whenthe power present in the first power signal for the first responsesignal at the first time is greater than the power present in the secondpower signal for the second response signal at the first time, anddetermining that the portable electronic device is closer to the secondlocation at the first time when the power present in the second powersignal for the second response signal at the first time is greater thanthe power present in the first power signal for the first responsesignal at the first time; determine whether the portable electronicdevice is closer to the first location or the second location at thesecond time by comparing the power present in the first response signalfor the first response signal at the second time to the power present inthe second response signal for the second response signal at the secondtime, determining that the portable electronic device is closer to thefirst location at the second time when the power present in the firstpower signal for the first response signal at the second time is greaterthan the power present in the second power signal for the secondresponse signal at the second time, and determining that the portableelectronic device is closer to the second location at the second timewhen the power present in the second power signal for the secondresponse signal at the second time is greater than the power present inthe first power signal for the first response signal at the second time;and determine the direction of movement of the portable electronicdevice by determining whether the portable electronic device is closerto the first location or the second location at the first time,determining whether the portable electronic device is closer to thefirst location or the second location at the second time, and derivingthe direction of movement of the portable electronic device based on thedeterminations of whether the portable electronic device is closer tothe first location or the second location at the first and second times,respectively.
 5. The system of claim 1, wherein the first power signalfor the first response signal contains a first received signal strengthindicator (RSSI) amount indicating the measured power in the firstresponse signal, and wherein the second power signal for the secondresponse signal contains a second RSSI amount indicating the measuredpower in the second response signal.
 6. The system of claim 1, whereinat least one of the first RFID reader and the second RFID readercomprises an elliptical or circularly polarized antenna such that the atleast one of the first RFID reader and the second RFID readerrespectively transmits the corresponding one of the first locationsignal and the second location signal in orthogonal polarizations in thecorresponding first and second locations, respectively.
 7. The system ofclaim 6, wherein the first RFID reader is arranged on a first side of aroom of a building, and the second RFID reader is arranged on a secondside of the room distinct from the first side of the room.
 8. The systemof claim 1, wherein at least one of the first RFID reader and the secondRFID reader comprises an elliptical or circularly polarized antenna suchthat the at least one of the first RFID reader and the second RFIDreader respectively transmits the corresponding one of the firstlocation signal and the second location signal in orthogonalpolarizations in the corresponding first and second locations,respectively, wherein the first RFID reader is arranged in a room of abuilding, and the second RFID reader is arranged in a hallway outsidethe room of the building, and wherein the controller is configured todetermine whether the portable electronic device is transported from thehallway into the room, and whether the portable electronic device istransported from the room into the hallway.
 9. The system of claim 8,comprising: a third RFID reader arranged in the hallway at a thirdlocation distinct from the first and second locations, wherein the thirdRFID reader comprises: a third transceiver configured to transmit athird location signal from the third location and to receive a thirdresponse signal from the portable electronic device when the portableelectronic device is within range of the third location to receive thethird location signal, a third power measurement unit configured tomeasure power present in the third response signal received by the thirdtransceiver of the third RFID reader, and a third control unitconfigured to generate a third power signal indicating the measuredpower in the third response signal received by the third transceiver ofthe third RFID reader; and wherein the third transceiver of the thirdRFID reader is configured to transmit the third power signal to thecontroller for the third response signal at the first time when thethird transceiver of the third RFID reader receives the third responsesignal at the first time, and to transmit the third power signal to thecontroller for the third response signal at the third time when thethird transceiver of the third RFID reader receives the third responsesignal at the third time, and wherein the controller is configured todetermine whether the portable electronic device is closer to one of thefirst RFID reader, the second RFID reader and the third RFID reader atthe first and second times, respectively, based on (i) the powerindicated in the first power signals received from the first RFID readerfor the first response signals at the first and second times,respectively, (ii) the power indicated in the second power signalsreceived from the second RFID reader for the second response signals atthe first and second times, respectively, and (iii) the power indicatedin the third power signals received from the third RFID reader for thethird response signals at the first and second times, respectively. 10.The system of claim 9, wherein the controller is configured to comparethe power indicated in the first power signals received from the firstRFID reader for the first response signals at the first and secondtimes, respectively, the power indicated in the second response signalsreceived from the second RFID reader for the second response signals forthe first and second times, and the third power signals received fromthe third RFID reader for the third response signals at the first andsecond times, respectively, and to determine whether the portableelectronic device is closer to one of the first RFID reader, the secondRFID reader and the third RFID reader at the first and second timesbased on which one of the first power signal, the second power signaland the third power signal indicates the greatest amount of power at thefirst and second times, respectively.
 11. The system of claim 1, whereinthe controller is configured to determine an amount of time that theportable electronic device is present in at least one of the first andsecond locations based on the first and second power signals over aperiod of time.
 12. The system of claim 1, in combination with aportable electronic device, wherein the portable electronic devicecomprises an RFID tag configured to transmit the first response signalwhen the portable electronic device is within range of the firstlocation to receive the first location signal, and to transmit thesecond response signal when the portable electronic device is withinrange of the second location to receive the second location signal. 13.The system of claim 12, wherein the RFID tag is a passive tag configuredto transmit the first response signal in response to receiving the firstlocation signal when the portable electronic device is within range ofthe first location to receive the first location signal, and to transmitthe second response signal in response to receiving the second locationsignal when the portable electronic device is within range of the secondlocation to receive the second location signal, wherein the RFID tagcomprises a unique identifier, wherein the RFID tag is configured totransmit the first response signal to the first RFID reader bymodulating the first location signal with the unique identifier of theRFID tag and transmitting the modulated first location signal with theunique identifier of the RFID tag, and wherein the RFID tag isconfigured to transmit the second response signal to the second RFIDreader by modulating the second location signal with the uniqueidentifier of the RFID tag and transmitting the modulated secondlocation signal with the unique identifier of the RFID tag.
 14. Thesystem of claim 12, wherein the RFID tag is an active tag having aunique identifier, and the portable electronic device comprises abattery power source configured to supply power to the RFID tag, whereinthe RFID tag is configured to generate and transmit the first responsesignal to the first RFID reader when the portable electronic device iswithin range of the first location, the first response signal containingthe unique identifier of the RFID tag, and wherein the RFID tag isconfigured to generate and transmit the second response signal to thesecond RFID reader when the portable electronic device is within rangeof the first location, the second response signal containing the uniqueidentifier of the RFID tag.
 15. The system of claim 12, wherein theportable electronic device comprises at least one processor and at leastone memory having recorded thereon operation instructions that the atleast one processor executes to perform operations of the at least oneprocessor of the portable electronic device, wherein the controller isconfigured to control at least one operation of the portable electronicdevice by authorizing or disallowing the at least one operation to beexecuted by the at least one processor of the portable electronic devicebased on whether at least one of (i) the first RFID reader receives thefirst response signal from the portable electronic device and (ii) thesecond RFID reader receives the second response signal from the portableelectronic device.
 16. The system of claim 12, wherein the controller isconfigured to control the first RFID reader to transmit a firstauthorization signal to the portable electronic device when the firstRFID reader receives the first response signal from the portableelectronic device, the first authorization signal authorizing the atleast one processor of the portable electronic device to execute a firstset of operations, wherein the controller is configured to control thesecond RFID reader to transmit a second authorization signal to theportable electronic device when the second RFID reader receives thesecond response signal from the portable electronic device, the secondauthorization signal authorizing the at least one processor of theportable electronic device to execute a second set of operations,wherein the at least one processor of the portable electronic device isconfigured to execute the first set of operations when the RFID tag ofthe portable electronic device receives the first authorization signal,and wherein the at least one processor of the portable electronic deviceis configured to execute the second set of operations when the RFID tagof the portable electronic device receives the second authorizationsignal.
 17. The system of claim 16, wherein the at least one processorof the portable electronic device is configured to execute the first setof operations while the RFID tag of the portable electronic devicereceives the first location signal when the portable electronic deviceis in the first location, and wherein the at least one processor of theportable electronic device is configured to execute the second set ofoperations while the RFID tag of the portable electronic device receivesthe second location signal when the portable electronic device is in thesecond location.
 18. The system of claim 16, wherein the at least oneprocessor of the portable electronic device is configured toauthenticate the controller when the RFID tag receives the firstauthorization signal, and control the RFID tag to transmit a firstauthentication signal to the controller upon authenticating thecontroller, and wherein the at least one processor of the portableelectronic device is configured to authenticate the controller when theRFID tag receives the second authorization signal, and control the RFIDtag to transmit a second authentication signal to the controller uponauthenticating the controller.
 19. The system of claim 1, wherein thecontroller is configured to control the first RFID reader to transmit afirst authorization signal to the portable electronic device when thefirst RFID reader receives the first response signal from the portableelectronic device, the first authorization signal authorizing theportable electronic device to execute a first set of operations whilethe portable electronic device receives the first location signal, andwherein the controller is configured to control the second RFID readerto transmit a second authorization signal to the portable electronicdevice when the second RFID reader receives the second response signalfrom the portable electronic device, the second authorization signalauthorizing the portable electronic device to execute a second set ofoperations while the portable electronic device receives the secondlocation signal.
 20. The system of claim 19, wherein the controller isconfigured to modify at least one of the first set of operations and thesecond set of operations.
 21. The system of claim 1, wherein the firstRFID reader is configured to transmit the first location signal at afirst frequency, and the second RFID reader is configured to transmitthe second location signal at a second frequency different from thefirst frequency, wherein the controller is configured to control thefirst RFID reader to transmit a first authorization signal to theportable electronic device when the first RFID reader receives the firstresponse signal from the portable electronic device at the firstfrequency, the first authorization signal authorizing the portableelectronic device to execute a first set of operations while theportable electronic device receives the first location signal, andwherein the controller is configured to control the second RFID readerto transmit a second authorization signal to the portable electronicdevice when the second RFID reader receives the second response signalfrom the portable electronic device at the second frequency, the secondauthorization signal authorizing the portable electronic device toexecute a second set of operations while the portable electronic devicereceives the second location signal.
 22. The system of claim 21, whereinthe controller is configured to control the first and second RFIDreaders to respectively change the first and second frequencies at apredetermined time.
 23. A method of detecting direction of movement, themethod comprising: transmitting, from a first radio frequencyidentification (RFID) reader arranged in a first location, a firstlocation signal from the first location; receiving, by the first RFIDreader, a first response signal from a portable electronic device whenthe portable electronic device is within range of the first location toreceive the first location signal; measuring, by the first RFID reader,power present in the first response signal received by the first RFIDreader; generating, by the first RFID reader, a first power signalindicating the measured power in the first response signal received bythe first RFID reader; transmitting, from a second RFID reader arrangedin a second location distinct from the first location, a second locationsignal from the second location; receiving, by the second RFID reader, asecond response signal from the portable electronic device when theportable electronic device is within range of the second location toreceive the second location signal; measuring, by the second RFIDreader, power present in the second response signal received by thesecond RFID reader; generating, by the second RFID reader, a secondpower signal indicating the measured power in the second response signalreceived by the second RFID reader; and determining, by a controllerexternal to the first and second RFID readers, a direction of movementof the portable electronic device relative to the first and secondlocations during a first time and a second time subsequent to the firsttime, wherein the first RFID reader transmits the first power signal tothe controller for first response signal at the first time when thefirst RFID reader receives the first response signal at the first time,and transmits the first power signal to the controller for the firstresponse signal at the second time when the first RFID reader receivesthe first response signal at the second time, wherein the second RFIDreader transmits the second power signal to the controller for thesecond response signal at the first time when the second RFID readerreceives the second response signal at the first time, and transmits thesecond power signal to the controller for the second response signal atthe second time when the second transceiver of the second RFID readerreceives the second response signal at the second time, and wherein thecontroller compares a respective amount of power indicated in the firstand second power signals for the first and second response signalsrespectively received at the first and second times, and determines thedirection of movement of the portable electronic device during the firstand second times based on the comparative amount of power in the firstand second power signals for the first and second response signalsrespectively received at the first and second times.